Task 3An engineer wants to design a lightweight strong tie-rod as shown in figure 1. Consider a design thatcalls for a cylindrical tie-rod of given length L that must carry a tensile force F as in Figure 1, it mustnot yield, but remain elastic. Where A is the area of the cross-section, ay is the yield strength and pis the density of the material of which it is made. Section area A must be sufficient to carry the tensileload F without yielding.Section area AForce FDeflection 8Lo-Figure 1: Light strong tie-radNote: You can prefer the attached document for the property charts.Consider the mass equation and tensile load equation for a tie rod.There are two constraints.Fracture Toughness K₁ > 15MP¹/2Mass of the Rod-m= AlpAs A must be sufficient to carry the tensile load F without yielding -2.1 Apply the first step of the material selection process and derive design requirements undertranslation.2.2 Derive the material index for the selection referring to the attached formulas.2.3 Name the two appropriate material property charts.2.4 If the ay = 1, mark the property charts accordingly, and complete the 2nd and 3rd selecting stagesof Material selecting criteria. Mention your conclusion over each property chart.2.5 List down your final short-listed materials and mention your suggestion for the best material outof the selected materials. (Refer supportive data)

An engineer wants to design a lightweight strong tie-rod as shown in figure 1. Consider a design that calls for a cylindrical tie-rod of given length L that must carry a tensile force F as in Figure 1, I must not yield, but remain elastic. Where A is the area of the cross-section, ay is the yield strength and p is the density of the material of which it is made. Section area A must be sufficient to carry the tensile load F without yielding Section area A Force F Deflection & Figure E Light strong tie-roat Note: You can prefer the attached document for the property charts. Consider the mass equation and tensile load equation for a tie rod. There are two constraints. Fracture Toughness , >15 Mass of the Rod- - Alp As A must be sufficient to carry the tensile load F without yieldings, 2.1 Apply the first step of the material selection process and derive design requirements under 2.2 Derive the material index for the selection referring to the attached formulas 2.3 Name the two appropriate material property charts. 2.4 If the ay = 1, mark the property charts accordingly, and complete the 2 and 3 selecting stages of Material selecting criteria. Mention your conclusion over each property chart.

An engineer wants to design a lightweight strong tie-rod as shown in figure 1. Consider a design that calls for a cylindrical tie-rod of given length L that must carry a tensile force F as in Figure 1, I must not yield, but remain elastic. Where A is the area of the cross-section, ay is the yield strength and p is the density of the material of which it is made. Section area A must be sufficient to carry the tensile load F without yielding Section area A Force F Deflection & Figure E Light strong tie-roat Note: You can prefer the attached document for the property charts. Consider the mass equation and tensile load equation for a tie rod. There are two constraints. Fracture Toughness , >15 Mass of the Rod- - Alp As A must be sufficient to carry the tensile load F without yieldings, 2.1 Apply the first step of the material selection process and derive design requirements under 2.2 Derive the material index for the selection referring to the attached formulas 2.3 Name the two appropriate material property charts. 2.4 If the ay = 1, mark the property charts accordingly, and complete the 2 and 3 selecting stages of Material selecting criteria. Mention your conclusion over each property chart.

College Physics

11th Edition

ISBN:9781305952300

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter1: Units, Trigonometry. And Vectors

Section: Chapter Questions

Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...

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